The Apache Kafka connectors for Structured Streaming are packaged in Databricks Runtime.
You use the
kafka connector to connect to Kafka 0.10+ and the
kafka08 connector to connect to Kafka 0.8+ (deprecated).
Connect Kafka on HDInsight to Azure Databricks
Create an HDInsight Kafka cluster.
See Connect to Kafka on HDInsight through an Azure Virtual Network for instructions.
Configure the Kafka brokers to advertise the correct address.
Follow the instructions in Configure Kafka for IP advertising. If you manage Kafka yourself on Azure Virtual Machines, make sure that the
advertised.listenersconfiguration of the brokers is set to the internal IP of the hosts.
Create an Azure Databricks cluster.
Follow the instructions in Quickstart: Run a Spark job on Azure Databricks using the Azure portal.
Peer the Kafka cluster to the Azure Databricks cluster.
Follow the instructions in Peer virtual networks.
Validate the connection by testing the scenarios described in Quickstart and Production Structured Streaming with Kafka notebook.
The schema of the records is:
key and the
value are always deserialized as byte arrays with the
Use DataFrame operations (
cast("string"), udfs) to explicitly deserialize the keys and values.
Let’s start with a the canonical WordCount example. The following notebook demonstrates how to run WordCount using Structured Streaming with Kafka.
This notebook example uses Kafka 0.10. To use Kafka 0.8, change the format to
kafka08 (that is,
Kafka WordCount with Structured Streaming notebook
Refer to the Spark Structured Streaming + Kafka Integration Guide for the comprehensive list of configurations. To get you started, here is a subset of configurations.
As Structured Streaming is still under development, this list may not be up to date.
There are multiple ways of specifying which topics to subscribe to. You should provide only one of these parameters:
|Option||Value||Supported Kafka Versions||Description|
|subscribe||A comma-separated list of topics.||0.8, 0.10||The topic list to subscribe to.|
|subscribePattern||Java regex string.||0.10||The pattern used to subscribe to topic(s).|
||0.8, 0.10||Specific topicPartitions to consume.|
Other notable configurations:
|Option||Value||Default Value||Supported Kafka Versions||Description|
|kafka.bootstrap.servers||Comma-separated list of host:port.||empty||0.8, 0.10||[Required] The Kafka
||0.10||[Optional] Whether to fail the query when it’s possible that data was lost. Queries can permanently fail to read data from Kafka due to many scenarios such as deleted topics, topic truncation before processing, and so on. We try to estimate conservatively whether data was possibly lost or not. Sometimes this can cause false alarms. Set this option to
|minPartitions||Integer >= 0, 0 = disabled.||0 (disabled)||0.10||[Optional] Minimum number of partitions to read from Kafka. With Spark 2.1.0-db2 and above, you can configure Spark to use an arbitrary minimum of partitions to read from Kafka using the
|kafka.group.id||A Kafka consumer group ID.||not set||0.10||[Optional] Group ID to use while reading from Kafka. Supported in Spark 2.2+. Use this with caution. By default, each query generates a unique group ID for reading data. This ensures that each query has its own consumer group that does not face interference from any other consumer, and therefore can read all of the partitions of its subscribed topics. In some scenarios (for example, Kafka group-based authorization), you may want to use specific authorized group IDs to read data. You can optionally set the group ID. However, do this with extreme caution as it can cause unexpected behavior.
* Concurrently running queries (both, batch and streaming) with the same group ID are likely interfere with each other causing each query to read only part of the data.
* This may also occur when queries are started/restarted in quick succession. To minimize such issues, set the Kafka consumer configuration
See Structured Streaming Kafka Integration Guide for other optional configurations.
You should not set the following Kafka parameters for the Kafka 0.10 connector as it will throw an exception:
group.id: Setting this parameter is not allowed for Spark versions below 2.2.
auto.offset.reset: Instead, set the source option
startingOffsetsto specify where to start. To maintain consistency, Structured Streaming (as opposed to the Kafka Consumer) manages the consumption of offsets internally. This ensures that you don’t miss any data after dynamically subscribing to new topics/partitions.
startingOffsetsapplies only when you start a new Streaming query, and that resuming from a checkpoint always picks up from where the query left off.
key.deserializer: Keys are always deserialized as byte arrays with
ByteArrayDeserializer. Use DataFrame operations to explicitly deserialize the keys.
value.deserializer: Values are always deserialized as byte arrays with
ByteArrayDeserializer. Use DataFrame operations to explicitly deserialize the values.
enable.auto.commit: Setting this parameter is not allowed. Spark keeps track of Kafka offsets internally and doesn’t commit any offset.
interceptor.classes: Kafka source always read keys and values as byte arrays. It’s not safe to use
ConsumerInterceptoras it may break the query.
To enable SSL connections to Kafka, follow the instructions in the Confluent documentation Encryption and Authentication with SSL. You can provide the configurations described there, prefixed with
kafka., as options. For example, you specify the trust store location in the property
We recommend that you:
- Store your certificates in Azure Blob storage or Azure Data Lake Storage Gen2 and access them through a DBFS mount point. Combined with cluster and job ACLs, you can restrict access to the certificates only to clusters that can access Kafka.
- Store your certificate passwords as secrets in a secret scope.
Once paths are mounted and secrets stored, you can do the following:
df = spark.readStream \ .format("kafka") \ .option("kafka.bootstrap.servers", ...) \ .option("kafka.ssl.truststore.location", <dbfs-truststore-location>) \ .option("kafka.ssl.keystore.location", <dbfs-keystore-location>) \ .option("kafka.ssl.keystore.password", dbutils.secrets.get(scope=<certificate-scope-name>,key=<keystore-password-key-name>)) \ .option("kafka.ssl.truststore.password", dbutils.secrets.get(scope=<certificate-scope-name>,key=<truststore-password-key-name>))